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The 6666 Problem

Published online by Cambridge University Press:  23 January 2015

Roger Eggleton  and
Krzysztof Ostaszewski
Roger Eggleton
Affiliation:
Mathematics Department, Illinois State University, Normal, IL 61790, USA, e-mail:[email protected]
Krzysztof Ostaszewski
Affiliation:
Mathematics Department, Illinois State University, Normal, IL 61790, USA, e-mail:[email protected]
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Extract

How many times must a die be thrown to get four consecutive sixes? More generally, and more precisely,

Q1. What is the expected number of times we must throw a die to get n consecutive sixes?

The answer, rather suggestively for the numerologically inclined, turns out to be

A1. The expected number of throws is 6 + 62 + 63 + … + 6n.

In some well-known dice games players throw several dice at the same time: in craps a pair (brace) of dice is thrown, while in yahtzee, yam and balut, up to five dice are thrown at a time. However, Q1 is not the same as

Type
Articles
Information
The Mathematical Gazette , Volume 96 , Issue 535 , March 2012 , pp. 39 - 48
Copyright
Copyright © The Mathematical Association 2012

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References

1. Gajek, L. and Ostaszewski, K., Financial risk management for pension plans, Elsevier, Amsterdam (2004).Google Scholar
2. Muldowney, Patricka, Ostaszewski, Krzysztof and Wojdowski, Wojciech, The Darth Vader rule, Tatra Mountain Journal, to appear.Google Scholar
3. Fu, J. C. and Koutras, M. V., Distribution theory of runs: a Markov chain approach, J. Amer, Statistical Assoc. 89 (1994) pp. 10501058.Google Scholar
4. Fu, J. C. and Lou, W. Y., Distribution theory of runs and patterns and its applications: A finite Markov chain imbedding approach, World Scientific, River Edge, NJ (2003).Google Scholar
5. Moivre, A. de, The doctrine of chance, H. Woodfall, London (1738).Google Scholar
6. Simpson, T., The nature and laws of chance, Edward Cave, London (1740).Google Scholar
7. de Laplace, P.S., Théorie analytique des probabilités, V. Courcier, Paris (1812).Google Scholar
8. Todhunter, I., A history of the mathematical theory of probability: from the time of Pascal to that of Laplace, Macmillan, Cambridge (1865).Google Scholar
9. Whitworth, W. A., Choice and chance, Deighton Bell, Cambridge (1870).Google Scholar
10. Wald, A. and Wolfowitz, J., On a test whether two samples are from the same population, Ann. Math. Stat. 11 (1940) pp. 147162.Google Scholar
11. Mood, A. M., The distribution theory of runs, Ann. Math. Stat. 11 (1940) pp. 367392.Google Scholar
12. Feller, W., An introduction to probability theory and its applications, Vol. I (3rd edn.), Wiley, New York (1968).Google Scholar
13. Li, S., A martingale approach to the study of occurrence of sequence patterns in repeated experiments, Annals Prob. 8 (1980) pp. 11711176.Google Scholar